Dental implant

ABSTRACT

A dental prosthesis comprises an implant, an abutment and a crown. The implant has distal and proximal portions with the implant proximal portion including distal and proximal segments. The implant proximal segment has an outer surface. The abutment has distal and proximal segments and defines an abutment shoulder therebetween. The abutment shoulder is configured to circumferentially engage the outer surface of the implant proximal segment such that an implant abutment joint is defined therebetween. The crown is configured to be positioned over the abutment and the implant such that the crown covers the implant abutment joint. The implant proximal segment has an annular concave cross-section such that the crown distal end has a rounded shape to reduce the potential for stress cracking of the crown.

CROSS-REFERENCE TO RELATED APPLICATIONS

This application claims priority to U.S. Provisional Application Ser.No. 60/795,876, filed on Apr. 28, 2006 and entitled DENTAL IMPLANT, theentire contents of which is expressly incorporated by reference herein.

STATEMENT RE: FEDERALLY SPONSORED RESEARCH/DEVELOPMENT

(Not Applicable)

BACKGROUND

The present invention relates generally to dental prostheses and, moreparticularly, to a dental prosthesis including an implant, an abutmentwhich is attachable to the implant, and a crown which is attachable tothe abutment and the implant such that the joint defined between theabutment and the implant is covered and effectively sealed.

As is well known in the art, dental prostheses are commonly used in thedental field to address extensive damage to teeth caused by injury ordisease. A typical dental prosthesis comprises an implant, an abutmentand a crown. The implant itself generally comprises a metallic componentwhich is implanted or embedded into the bony structure of a patient'smouth subsequent to the removal of the damaged tooth alone or incombination with one or more adjacent teeth. The installation of theimplant is typically initiated by forming a hole in the bony structureand then embedding the implant into the bony structure by screwing theimplant into the hole via threads formed on an exterior of the implant.

After the implant has been embedded into the bony structure, the bonenormally recovers and grows around the implant, thus resulting inbone/implant integration. To enhance the integration of the implant intothe bone, the implant may be coated with a surface finish such as etchedtitanium and/or a biocompatible coating such as hydroxylapatite (HA).Subsequent to the embedding of the implant into the bony structure, theabutment is attached to the implant. Such attachment may be accomplishedthrough the use of a cement, by the engagement of complementary male andfemale threads formed on or in the abutment and implant, or by themating of corresponding tapers or other geometries formed on or in theabutment and implant.

When attached to the implant, a portion of the abutment extends abovethe gum line of the patient for purposes of facilitating attachment ofthe crown to the implant. If the implant is embedded into the bonystructure such that the implant is completely disposed below orsubmerged within the gum line of the patient, the attachment of theabutment to the implant requires a second surgical procedure forpurposes of accessing the implant. However, if the implant is embeddedinto the bony structure in a manner wherein a portion thereof protrudesabove the patient's gum line, then the attachment of the abutment may beaccomplished without the need for the second surgical procedure, thusrequiring only the initial surgical procedure to complete theimplantation or embedding process.

As was previously indicated, the crown of the dental prosthesis isattached to that portion of the abutment which extends above thepatient's gum line. In the prior art, crowns are fabricated andinstalled in accordance with well-established procedures which includetaking a transfer impression of the exposed portion of the abutment toestablish with precision its configuration and orientation, thusinsuring a complete attachment of the crown thereto. The exposed portionof the abutment to which the crown is attached may have the natural formof a prepared tooth, or an artificial form of a particular geometryadapted to achieve a secure attachment of the crown. The attachment ofthe crown to the abutment is typically accomplished through the use ofan adhesive and/or cement, or through the engagement of correspondingmale and female threads on or in the crown and abutment to each other.The attachment of the crown to the abutment completes the assembly ofthe dental prosthesis.

As will be recognized from the aforementioned description of the dentalprosthesis, the assembly thereof results in the formation of severaljoints. These joints include the joint formed by the attachment of thecrown to the abutment, and the joint formed by the attachment of theabutment to the implant. Of these joints, that joint considered mostimportant in relation to the long-term viability of the prosthesis isthe joint between the implant and the abutment which is commonlyreferred to as the implant abutment joint or “IAJ”.

Recent research in the dental field has suggested that the IAJ plays akey role in bone loss around the implant. Though such bone loss has notbeen well studied or well documented, it is believed to be a commonoccurrence which is at least partially attributable to the IAJ servingas a site for bacterial invasion and colonization. Over time, such boneloss can compromise the integrity of the implant or cause its failure bybreaking loose from the bony structure into which the implant isembedded.

Obviously, such failure, in addition to providing inconvenience anddiscomfort for the patient, is of serious medical concern due to theresulting bone loss or mutilation potentially rendering the installationof a replacement implant difficult or impossible. The joint formed bythe attachment of the crown to the abutment is also susceptible tobacterial invasion which contributes to bone loss around the implant.

The present invention addresses the susceptibility of the IAJ and thecrown/abutment joint to bacterial infestation by providing a dentalprosthesis which is configured to effectively cover and seal thesejoints. In addition, the dental prosthesis of the present invention alsoprevents micro-movement between the abutment and the implant at the IAJwhich, under the forces of mastication (i.e., chewing), can result inthe development of micro-gaps at the IAJ. Such micro-gaps can harborbacteria which can lead to inflammation and, ultimately, failure of theimplant.

BRIEF SUMMARY

Provided is a dental prosthesis which comprises an implant, an abutmentand a crown. The implant is adapted to be embedded into the bonystructure of a patient's mouth. The abutment is attached to the implantin a manner wherein an implant abutment joint is defined therebetween.The crown is attached to the abutment and the implant in a mannerwherein the implant abutment joint is covered by the crown. Theattachment of the crown to the abutment and implant may be facilitatedthrough the use of adhesive (e.g., dental cement) extending between thecrown and the implant (i.e., crown implant joint).

The adhesive within the crown implant joint effectively seals theimplant abutment joint as well as protects the crown implant joint. Moreparticularly, the adhesive isolates such joints from the gum line in thepatient in order to prevent migration of bacteria into the joints. Theimplant has distal and proximal portions with the implant proximalportion including distal and proximal segments. The implant proximalsegment includes an outer surface. The abutment also has distal andproximal portions with distal and proximal ends being disposedrespectively adjacent thereto. The abutment distal and proximal portionsdefine an abutment shoulder therebetween.

Importantly, the abutment shoulder is configured to circumferentiallyengage the outer surface of the implant proximal segment with increasedjoint surface area which thereby improves joint strength. In addition,the circumferential engagement between the abutment shoulder and theimplant provides improved resistance to micro-movement of the abutmentrelative to the implant. The elimination of such micro-movement reducesthe risk of cracking of the adhesive and also minimizes the developmentof micro-gapping at the joint which, in turn, reduces the potential forperiodontal pathogens. The implant abutment joint and the crown implantjoint are sealed from bacterial invasion due to the positioning of thecrown over the abutment and implant.

The implant may be comprised of an elongate, externally threaded implantdistal portion which is insertable into the bony structure of thepatient's mouth. The implant proximal portion itself includes distal andproximal segments. The implant distal segment may have a generallycylindrical outer surface or it may be circumferentially undercut. Thecircumferential undercut which defines the implant distal segmentinterconnects the implant distal portion to the implant proximalsegment. The implant proximal segment may have an outer surface whichmay be tapered or concave.

If tapered, the implant proximal segment is preferably conically shapedat an angle of about 45° although other angles are contemplated. Morepreferably, the implant proximal segment is formed at an angle of lessthan about 45° and greater than about 3° relative to an axis of theimplant. If concave, the implant proximal segment may itself includeconical portions which interface with the crown and are thereforepreferably formed at the above-mentioned half-angles of between about45° and 3° to avoid cracking of adhesive between the crown and implantwhile eliminating the need for overly-tight manufacturing toleranceswhich increase manufacturing costs.

The abutment may include an abutment cavity formed in the abutmentproximal portion adjacent to the abutment shoulder. Preferably, theabutment cavity is formed complementary to the outer surface of theimplant proximal segment in order to facilitate the circumferentialengagement of the abutment shoulder to the outer surface. The abutmentproximal portion engages the outer surface of the implant proximalsegment at a lower end of the abutment proximal portion. Additionally,it is contemplated that the abutment cavity may be configured to engagethe outer surface of the implant proximal segment in surface-to-surfaceor edge-to-surface contact therebetween.

The abutment distal portion defines an abutment shaft. Extending axiallywithin the implant proximal end is an implant bore which is sized andconfigured to receive the abutment shaft. In one embodiment, the implantbore may have a generally circular cross-sectional configuration withthe abutment shaft being of complementary cylindrical configurationalthough other configurations are contemplated. The abutment distalportion or abutment shaft may be advanced into the implant bore and maybe secured therewithin through the use of adhesive.

Alternatively, the implant bore may be internally threaded with theabutment distal portion or abutment shaft being externally threaded tofacilitate threadable engagement therebetween. The abutment proximalportion may have a frusto-conically shaped outer surface such that theabutment forms a truncated cone. The abutment may optionally include anabutment neck formed adjacent the abutment shoulder and which has agenerally reduced cross-sectional area in an axial orientation ascompared to the cross-sectional configuration of the immediatelyadjacent portions of the abutment. Advantageously, the abutment neckminimizes the overall size of the abutment while still providing aconfiguration which may effectively engage the outer surface of theimplant proximal segment.

The crown of the dental prosthesis includes a crown distal portion whichitself defines a crown distal end having a crown cavity disposedtherewithin. The crown cavity has a shape which is complementary to theouter surface of the abutment proximal portion as well as the outersurface of the implant proximal segment. Receipt of the abutmentproximal portion and implant proximal segment into the crown cavityresults in engagement of the crown distal portion to the implantproximal segment via direct contact therebetween. In this manner, theimplant abutment joint defined between the abutment proximal portion andthe implant proximal end is covered and may be thereafter sealed throughthe use of adhesive.

In a further embodiment, the implant proximal segment may have agenerally circumferential or annular concave cross-section such that thecrown distal end can be provided with a complementary rounded or bluntcircumferential edge instead of a less desirable circumferential knifeedge configuration. The rounded shape of the crown distal end providesincreased surface to more uniformly distribute occlusal forces appliedto the joint.

As was mentioned above, such occlusal forces are typically the result ofmastication (i.e., chewing) and are transmitted in an axial directionfrom the crown to the implant. The uniform distribution of the occlusalforces at the crown distal end reduces the susceptibility of a failureof the crown distal end due to overstressing and cracking. In addition,formation of the concave cross-section on the implant proximal segmentmay further reduce the loads placed on the adhesive which may lead tothe failure of the adhesive joint between the crown distal end and theimplant proximal segment.

Further, in accordance with the dental prosthesis, there is provided amethod of installing the dental prosthesis into a patient comprising theinitial step of drilling a hole into the bony structure of the patient'smouth or oral cavity. Thereafter, the implant of the dental prosthesismay be threaded into the hole in the bony structure. The abutment maythen be attached to the implant in a manner wherein the implant abutmentjoint is defined between the abutment and the implant.

The layer of adhesive may be applied to exposed portions of the abutmentand the implant which interface with the crown cavity. The crown maythen be attached to the abutment and the implant in a manner wherein theimplant abutment joint is covered by the crown. The flow of adhesivebetween the crown and the implant seals the implant abutment joint aswell as the joint between the crown and the implant. The abutment may bejoined to the implant through the use of the adhesive and/or viathreadable engagement.

BRIEF DESCRIPTION OF THE DRAWINGS

These and other features and advantages of the various embodimentsdisclosed herein will be better understood with respect to the followingdescription and drawings in which like numbers refer to like partsthroughout and in which:

FIG. 1 is an exploded perspective view of a dental prosthesisconstructed in accordance with an embodiment and illustrating animplant, an abutment and a crown of the dental prosthesis;

FIG. 2 is a perspective view of the dental prosthesis of FIG. 1 in anassembled state;

FIG. 3 is a cross-sectional partial view of the dental prosthesis andillustrating an implant proximal segment and circumferentially engagingwith an abutment shoulder and further illustrating the crown beingpositioned over the abutment and implant and covering an implantabutment joint;

FIG. 4 is a cross-sectional view of the dental prosthesis which issubstantially similar to that shown in FIG. 3 but illustrating animplant distal segment having an undercut configuration generallyconfigured as a continuous radius;

FIG. 5 is a cross-sectional view of the dental prosthesis in aconfiguration similar to FIG. 4 but illustrating the undercut configuredas a short conical portion transitioning into an implant body via acircumferential radius;

FIG. 6 is a cross-sectional view of the dental prosthesis substantiallysimilar to that which is shown in FIGS. 3 and 4 but omitting an abutmentneck of the abutment;

FIG. 7 is a cross-sectional view of the dental prosthesis substantiallysimilar to that shown in FIG. 6 but including the configuration of theimplant having the undercut as shown in FIG. 4;

FIG. 8 is a cross-sectional view of the dental prosthesis andillustrating the implant proximal segment having a concavecross-section;

FIG. 8 a is an enlarged cross-sectional view of the dental prosthesisillustrating the implant abutment joint;

FIG. 9 is a cross-sectional view of the dental prosthesis substantiallysimilar to that which is shown in FIG. 8 but including the configurationof the implant having the undercut as shown in FIG. 4;

FIG. 9 a is an enlarged cross-sectional view of the abutment of FIG. 9;

FIG. 10 is a cross-sectional view of the dental prosthesis and which isconfigured substantially similar to that shown in FIG. 4 but wherein theabutment shoulder is configured to directly engage a top portion of theimplant;

FIG. 10 a is an enlarged cross-sectional view of the dental prosthesisof FIG. 10 and illustrating the configuration of the abutment; and

FIG. 11 is a cross-sectional view substantially similar to that shown inFIG. 10 but which includes the configuration of the implant as shown inFIG. 8.

DETAILED DESCRIPTION

Referring now to the drawings wherein the showings are for purposes ofillustrating various embodiments of the present invention only and notfor purposes of limiting the same, FIGS. 1-11 depict a dental prosthesis10 which, in its broadest sense, comprises an implant 20, an abutment 50and a crown 80. The implant 20 is adapted to be embedded into the bonystructure of a patient's mouth or oral cavity. The implant 20 itselfincludes an elongate implant distal portion 26 which defines an implantdistal end 22. The implant distal portion 26 may be further divided intoan implant body 32 and an implant trunk 31. The implant distal portion26 may further include external threads 33 formed on the implant body 32which are preferably configured to be threadably engaged to the bonystructure.

The implant 20 may further include an implant neck or implant proximalportion 28. As can be seen in the figures, the implant proximal portion28 is separated from the implant trunk 31 by an annular implant shoulder30. Depending on the specific configuration of the implant proximalportion 28, the cross-sectional area of the implant proximal portion 28may slightly exceed the cross-sectional area of the implant trunk 31resulting in the formation of the annular implant shoulder 30therebetween. As was earlier mentioned, the implant trunk 31 is disposedabove the implant body 32 and serves as the portion of the implant 20that connects the implant body 32 to the implant proximal portion 28.

The implant proximal portion 28 itself may be comprised of an implantdistal segment 37 and an implant proximal segment 34. The implant distaland proximal segments 37, 34 converge at a prosthetic margin 40. Theimplant proximal portion 28 further defines an implant proximal end 24which may include an implant bore 42 formed therewithin. The implantbore 42 may have a variety of axial cross-sectional configurations suchas hexagonal and/or cylindrical cross-sections and is generallyconfigured to extend axially at least partially through the implantproximal portion 28 and into the implant distal portion 26. As can beseen in the figures, the implant bore 42 may extend to approximately themid-point of the implant distal portion 26.

The implant 20 may be fabricated from a metallic material which ispreferably a biocompatible material such as titanium or other suitablematerials. Additionally, certain areas of the implant 20 such as theimplant distal portion 26 may be coated with hydroxylapatite (HA) orother suitable biocompatible materials in order to assist in theintegration of the implant 20 to the bony structure of the patient'smouth. Additionally, the implant distal portion 26 may be etched with asuitable acid or other solution. The implant 20 may be provided in awide variety of sizes to accommodate dental structures of the patient.In this regard, the implant 20 may be provided in a diameter of betweenabout 3.5 millimeter (mm) to about 6.0 mm although other sizes arecontemplated to fit different patients. Likewise, the implant 20 may beprovided in a variety of lengths such as from about 10 mm to about 16 mmalthough longer and shorter lengths are contemplated.

The dental prosthesis 10 further includes the abutment 50 which may beattached to the implant 20 in a manner to be described in greater detailbelow. The abutment 50 itself may comprise an elongate, cylindricallyconfigured, shaft-like abutment distal portion 56 and an abutmentproximal portion 58. The abutment proximal portion 58 may have afrusto-conical outer surface. As such, the abutment proximal portion 58may take the form of a truncated cone although other shapes arecontemplated. In the dental prosthesis 10, the abutment distal portion56 is preferably sized and configured as an abutment shaft 66 such thatan outer surface thereof is configured complementary to the implant bore42. More specifically, the abutment shaft 66 may be provided with acylindrical shape having an outer diameter that is slightly less thanthat of the implant bore 42.

Adhesive 100 may be applied to the abutment distal portion 56 prior toits advancement into the implant bore 42. Alternatively or incombination therewith, adhesive 100 may be injected into the implantbore 42 prior to the insertion of the abutment distal portion 56thereinto. The implant bore 42 may be sized and configured to provide agap between an abutment distal end 52 and a bottom of the implant bore42 such that adhesive 100 may accumulate and harden, therebystrengthening the bond between the abutment 50 and the implant 20. Ascan be seen, the advancement of the abutment distal portion 56 into theimplant bore 42 is terminated by the engagement of the abutment proximalportion 58 to the implant proximal end 24 (i.e., by direct contacttherebetween) and forming the implant abutment joint 44.

As will be described in greater detail below, the unique geometries ofthe implant proximal portion 28 in combination with the geometry of theabutment distal end 52 results in an improved interface at the implantabutment joint 44. As was earlier mentioned, the implant abutment joint44 is specifically configured to prevent or reduce micro-movementbetween the abutment 50 and implant 20 which, in turn, preventsmicro-movement between the crown 80 and the implant 20. Suchmicro-movement is typically the result of forces of mastication in anocclusal or axial direction (i.e. parallel to the implant longitudinalaxis). Over time, such micro-movement may result in micro-gappingbetween the crown 80 and tooth which may cause the adhesive 100 to crackunder the load and which may then allow the harboring of bacteria in thejoints of the dental prosthesis 10 and the premature failure thereof inaddition to formation of periodontal pathogens.

Advantageously, the dental prosthesis 10, in at least one embodiment, isuniquely configured to provide circumferential engagement of theabutment distal end 52 to the implant proximal segment 34 to preventmicro-movement therebetween. As was earlier mentioned, suchcircumferential engagement of the abutment distal end 52 to the implantproximal segment 34 provides for a more uniform and even distribution ofocclusal forces that are exerted by the crown 80 upon the implant 20.Such forces on the crown 80 are transmitted to the abutment 50 and tothe implant 20 at respective ones of the implant abutment joint 44 andthe crown implant joint.

More particularly, the circumferential engagement of the abutment 50 tothe implant 20 provides greater surface area of engagement between theimplant 20 and the abutment 50 which increases its resistance tomicro-movement therebetween. In addition, the configuration of the crownimplant joint allows for a reduction in the force per unit area. Thereduced force per unit area reduces susceptibility of adhesive 100failure (i.e., cracking of the adhesive 100) between the crown 80 andthe implant 20 such as may occur due to overloading of the adhesive 100bond over time. Furthermore, the circumferential engagement of theabutment distal end 52 to the implant proximal segment 34 reduces stresscracking of the crown 80 at its crown distal end 82 in direct contactwith the implant 20.

As can be seen in the figures, due to the configuration of an outersurface of the implant proximal segment 34 and the complementary matingsurfaces of the abutment proximal portion 58, when the abutment 50 isattached to the implant 20 in the above-described manner, the abutment50 is generally in continuous circumferential engagement such that outersurfaces thereof are in flush relationship to one another.

The dental prosthesis 10 further comprises the crown 80 which ispreferably fabricated from an inert biocompatible material such asceramic and/or metal and is preferably configured in a desired exteriorsurface configuration in a manner known in the art. The crown 80includes a crown distal portion 86 which defines the crown distal end82. Disposed within the crown distal end 82 is a crown cavity 90 whichis configured complementary to the abutment proximal portion 58 and theimplant proximal segment 34.

Depending on the configuration of the implant 20 and the abutment 50,the crown cavity 90 may include an annular crown chamfer 92 which isspecifically configured to circumferentially engage the implant proximalsegment 34 and/or an abutment shoulder 60 disposed between the abutmentdistal and proximal portions 56, 58. As will be described in greaterdetail below, the crown cavity 90 is adapted to engage the abutmentproximal portion 58 and therefore has a shape which is complementarythereto. Additionally, the crown chamfer 92 is adapted to receive theimplant proximal segment 34 and therefore has a shape which iscomplementary thereto.

In the dental prosthesis 10, attachment of the crown 80 to the abutment50 and/or implant 20 is facilitated through the use of an adhesive 100which may be applied to the outer surface of the abutment proximalportion 58 and may include the application of adhesive 100 to theabutment proximal end 54. Furthermore, adhesive 100 may be applied tothe implant proximal segment 34. The crown 80 is then advanced over theabutment 50 and implant 20 such that the abutment proximal portion 58 issnugly received into the crown cavity 90 and the crown distal end 82 iscircumferentially engaged to the abutment proximal segment. Ideally, thecrown 80 is sized and configured such that when the abutment proximalportion 58 is fully received into the crown cavity 90 and the crowndistal end 82 is engaged to the implant proximal segment 34, the crowndistal end 82 extends to and terminates at the prosthetic margin 40defined between the implant distal segment 37 and implant proximalsegment 34.

When the crown 80 is attached to the abutment 50 and implant 20 in theabove-described manner, the crown distal end 82, by virtue of itsextension to the prosthetic margin 40, is distal to (i.e., extendedbelow) the implant abutment joint 44 resulting in the crown distalportion 86 completely covering the implant abutment joint 44.Additionally, the adhesive 100 for securing the crown 80 to the abutmentproximal portion 58 and implant proximal segment 34 preferably extendsbetween the outer surface of the implant proximal segment 34 and thecrown cavity 90 adjacent the crown distal end 82. Importantly, uponcuring and/or hardening of the adhesive 100, the implant abutment joint44 is effectively sealed and thereby isolated from the deleteriouseffects of bacterial invasion, plaque and disease.

The cured and/or hardened adhesive 100 also prevents bacterial migrationbetween the crown 80 and implant 20 by sealing the joint between thecrown distal portion 86 and implant proximal segment 34. Also, sealed bythe curative adhesive 100 is the joint between the crown 80 and theabutment proximal portion 58. Thus, the adhesive 100 serves severalessential purposes which includes attachment of the crown 80 to theabutment 50 and implant 20, sealing of the implant abutment joint 44,and sealing of the crown implant joint for purposes of preventingbacterial invasion.

Referring more particularly now to FIG. 3, shown is the dentalprosthesis 10 wherein the abutment distal end 52 is specificallyconfigured to circumferentially engage the implant proximal segment 34.More particularly, FIG. 3 illustrates an embodiment of the dentalprosthesis 10 wherein the implant proximal segment 34 includes an outersurface which is tapered. More specifically, the tapered outer surfaceof the implant proximal segment 34 may be conically shaped in order tofacilitate circumferential engagement of the abutment distal end 52thereto. In one embodiment, the implant proximal segment 34 may beprovided at an angle indicated by the reference character α₁ as shown inFIGS. 3 and 10 a. Although the implant proximal segment 34 may beprovided in any configuration, the angular range for α₁ is preferably nogreater than about 45° and preferably less than about 3° relative to theimplant longitudinal axis.

As can be seen in the figures, the implant distal segment 37 of thedental prosthesis 10 may be generally cylindrically shaped althoughother configurations for the implant distal segment 37 are contemplated.The implant distal segment 37 is configured to interface with softtissue surrounding the bony structure into which the implant 20 isembedded. The implant distal segment 37 may have a height of about 1 mmalthough the implant distal segment 37 may be provided in any height.

Alternatively, as shown in FIGS. 4-5, the implant distal segment 37 maydefine a circumferential or annular undercut 38 between the implantdistal portion 26 and the implant proximal segment 34. In thisconfiguration of the dental prosthesis 10, the implant distal segment 37is interposed between the implant trunk 31 and the implant proximalsegment 34 and interconnects the two. The circumferential undercut 38 asshown in FIGS. 4-5 may have an arcuately shaped cross-section.

Such arcuate cross-section may be defined by a continuous radiusextending from the prosthetic margin 40 (i.e., at the convergence of theimplant distal and proximal segments 37, 34) and blending into theimplant trunk 31. Alternatively, the circumferential undercut 38 of theimplant distal segment 37 may be defined by a short conical or taperedsurface which extends from the prosthetic margin 40 toward the implanttrunk 31 and which blends into the implant trunk 31 by an annularradius.

As shown in FIGS. 1-9 a, the abutment shoulder 60 is specificallyconfigured to circumferentially engage the outer surface of the implantproximal segment 34. The abutment 50 may include an abutment cavity 62for at least partially receiving the outer surface of the implantproximal segment 34. As shown in FIGS. 3-7, the outer surface of theimplant proximal segment 34 may be tapered and the abutment cavity 62may have a conical shape in order to interface with the outer surface ofthe implant proximal segment 34. Optionally, the abutment cavity 62 mayhave a conical shape with a half angle that is slightly smaller than thehalf angle of the outer surface of the implant proximal segment 34.

In this manner, only a lower edge of the abutment proximal portion 58may engage the implant proximal segment 34 outer surface inedge-to-surface contact. Optionally, the abutment 50 and outer surfaceof the implant proximal segment 34 may be configured with substantiallyequal half angles to provide surface-to-surface contact between theabutment 50 and the implant 20. However, it is contemplated that theabutment cavity 62 may be provided in a variety of alternative shapesand sizes to provide the feature of circumferential engagementtherebetween. As was earlier mentioned, such configuration is believedto uniformly distribute occlusal forces imposed on the crown 80 and alsoprovide a greater area through which forces may be transferred betweenthe abutment 50 and the implant 20.

The abutment 50 may further include an abutment neck 64 disposedadjacent the abutment distal end 52 and the abutment shoulder 60. Theabutment neck 64 preferably has a reduced cross-section in an axialdirection relative to the cross-section of an immediately adjacentportion of the abutment 50. More particularly, the abutment neck 64provides a locally thinned area of the abutment 50 which allows for areduction in the overall volume occupied by the abutment 50 within thecrown cavity 90 but while still providing for circumferential engagementof the abutment shoulder 60 to the outer surface of the implant proximalsegment 34. In the figures, the abutment 50 can be seen as having agenerally frusto-conical configuration while allowing the abutmentproximal portion 58 outer surface to blend in with the implant proximalsegment 34.

The crown 80 includes a crown distal portion 86 which defines the crowndistal end 82 having the crown cavity 90 formed therein. The crowncavity 90 is configured to be complementary to the abutment proximalsegment such that the crown distal end 82 may also circumferentiallyengage the implant proximal segment 34 as shown in FIGS. 1-9 a. As wasearlier mentioned, receipt of the abutment proximal portion 58 andabutment proximal segment into the crown cavity 90 results in engagementof the crown distal portion 86 to the implant proximal segment 34 outersurface such that the crown implant joint is defined therebetween. Theimplant abutment joint 44 is covered by the crown distal portion 86 anda layer of adhesive 100 may be disposed between the implant proximalsegment 34 and the crown cavity 90 at the crown implant joint in orderto provide sealing engagement therebetween.

Regarding joining of the abutment 50 to the implant 20, the abutmentdistal portion 56 may be externally threaded with the abutment proximalportion 58 including a recess disposed within the abutment proximal end54 for receiving an implement such as a screwdriver to threadably rotatethe abutment 50. Additionally, the implant bore 42 may be internallythreaded. As such, attachment of the abutment 50 to the implant 20 maybe facilitated by threadable receipt of the abutment distal portion 56into the implant bore 42. Optionally, adhesive 100 may be providedbetween the implant bore 42 and the abutment distal portion 56 orabutment shaft 66 in order to secure the two components.

As can be seen in FIGS. 1-2 and 8-9 a, in a further embodiment, theimplant proximal segment 34 may have an annular concave cross-sectionalshape. The implant proximal segment 34 is configured to provide anarcuate interface between the implant proximal segment 34 and theimplant distal segment 37 (i.e., at the prosthetic margin 40). As shownin FIG. 9 a, the concave cross-section of the implant proximal segment34 may be defined by a radius extending directly upwardly from a tangentof the radius. Preferably, the radius intersects the prosthetic margin40 at an angle indicated by reference character α₁ and which ispreferably no greater than about 45° relative to the implantlongitudinal axis and no less than about 3° relative to the implantlongitudinal axis.

By limiting the angular orientation of the implant proximal segment 34to no greater than about 45°, the magnitude of vertical forcestransmitted from the crown 80 into the implant 20 across the adhesive100 may be minimized. By minimizing the magnitude of these verticalforces on the adhesive 100, the risk of cracking the adhesive isavoided. In addition, limiting the angular orientation of the implantproximal segment 34 to no greater than about 45° reduces the risk ofstress-cracking and resultant fracturing of the crown 80 at the crowndistal end 82 where the crown 80 engages the implant proximal segment34. On the other hand, by limiting the angular orientation of theimplant proximal segment 34 to no less that about 3° reduces oreliminates the need for overly-tight manufacturing tolerances of thecrown 80 and/or implant 20.

More specifically, maintaining the angular orientation of the implantproximal segment 34 to no less that about 3° allows for installation ofthe dental prosthesis 10 in keeping with material and methods ofdentistry known in the art. Finally, limiting the angular orientation tono less than about 3° reduces the risk of adhesive 100 cracking andfailure thereof between the crown 80 and implant 20 and/or abutment 50which would otherwise compromise the structural integrity of the crownimplant joint and/or crown abutment joint. It should be noted that therange of angular orientation described above for the implant proximalsegment 34 are applicable to all configurations of the dental prosthesis10 shown and described herein.

As can be seen in FIG. 9 a, the radius may transition into an upperconical surface 35 of the implant proximal segment 34. Preferably, theupper conical surface 35 is formed at an angle indicated in FIG. 9 a bythe reference character α₂ of at least about 3°, as discussed above,although it is contemplated that the upper conical surface 35 may beformed at the angular orientation of no greater than about 45° relativeto the implant longitudinal axis. The concave cross-section of theimplant proximal segment 34 provides a relatively large area upon whichforces from the crown 80 may be distributed into the implant 20. Theconcave cross-section provides a relatively large surface area and,therefore, results in reduced force per unit area that must be carriedby the adhesive 100 which bonds the crown 80 to the implant 20. In thismanner, the concave cross-section of the implant proximal segment 34eliminates or prevents failure or fracturing of the adhesive 100.

The implant proximal segment 34 may be defined by thepreviously-mentioned upper conical surface 35 and a lower conicalsurface 36 disposed adjacent the prosthetic margin 40. The lower conicalsurface 36 may preferably extend upwardly from the prosthetic margin 40at an angle α₁ of no greater than about 45° although other angles arecontemplated. As was earlier mentioned, the upper conical surface 35extends downwardly from the implant proximal end 24 and intersects theannular radius which also transitions into the lower conical surface 36.

As can be seen in FIG. 9 a, the upper and lower conical surfaces 35, 36may be joined via a circumferential radius. Preferably, the concavecross-section is configured such that the tangent is offset radiallyinwardly from the prosthetic margin 40 by about 0.2 mm to about 1.0 mm.Such offset is believed to provide an optimal joint configuration andmay reduce or eliminate adhesive 100 failure such as by cracking betweenthe crown 80 and the implant proximal segment 34. The crown distal end82 may have a radiused configuration formed complementary to the implantproximal segment 34 in order to eliminate stress over time.

As was earlier mentioned, the dental prosthesis 10 as shown in FIGS. 1-9a, may be configured such that the abutment shoulder 60 is configured tocircumferentially engage the outer surface of the implant proximalsegment 34. In this regard, the abutment 50 includes the abutment cavity62 which is likewise formed to be complementary to the outer surface ofthe implant proximal segment 34 to enable circumferential engagementtherebetween. As was earlier mentioned, such engagement may be asurface-to-surface or surface-to-line circumferential engagement. If anabutment neck 64 is provided in the abutment 50, the abutment neck 64 ispreferably configured to blend into the upper and lower conical surfaces35, 36 and radius of the implant proximal segment 34. The abutmentrecess 68 may be further provided in the abutment 50 in order tofacilitate insertion of the abutment shaft 66 into the implant bore 42.

Referring to FIGS. 10-11, the implant proximal segment 34 may beconfigured such that the abutment shoulder 60 engages an end face of theimplant proximal end 24 as opposed to circumferential engagementillustrated in FIGS. 1-9 a. As can be seen in FIG. 10, the implantdistal segment 37 may include the annular undercut 38 configurationshown in FIGS. 4 and 5 and as described above. The implant proximalsegment 34 may have the conical shape described above. As was alsodescribed above, the crown 80 covers the implant abutment joint 44 whenthe crown 80 is mounted on the abutment 50. More specifically, for theconfigurations shown in FIGS. 10 and 11, the crown 80 is configured toextend over and cover the implant abutment joint 44.

As shown in FIG. 11, the implant distal segment 37 may be configuredsubstantially similar to that shown in FIG. 10 but includes theconfiguration of the implant proximal segment 34 shown in FIG. 8 a. Forthe configuration shown in FIG. 11 where the implant proximal segment 34has a concave cross-section, the abutment 50 is preferably configuredsuch that the implant proximal segment 34 is substantially continuouswith the outer surface of the abutment proximal portion 58 when theabutment 50 is attached to the implant 20.

Having thus described various embodiments of the dental prosthesis 10constructed in accordance with the present invention, a method ofinstalling such prosthesis into a patient's mouth will now be described.Installation of the dental prosthesis 10 is initiated by first drillinga hole into the bony structure of the patient's mouth. Thereafter, theexternally-threaded implant distal portion 26 may be embedded into thebony structure of the patient's mouth by threadable engagement. Theimplant 20 is preferably embedded to a level such that the implantproximal segment 34 protrudes above the bony structure. However, theimplant proximal segment 34 may be disposed below, at, or above thepatient's gum line.

Subsequent to embedding the implant 20 into the bony structure, theabutment 50 is rigidly attached to the implant 20 in the above-describedmanner and may be accomplished through the use of an adhesive 100 and/orvia threadable engagement of the abutment 50 and implant 20 to oneanother. After attachment of the abutment 50 to the implant 20, atransfer cast is made of exposed portions of the abutment 50 and implant20. Such exposed portions include the outer surface of the implantproximal segment 34 and the frusto-conical outer surface of the abutmentproximal portion 58. The transfer cast is used to fabricate the crown 80in order to ensure complete coverage of exposed portions of the abutment50 and implant 20.

Subsequent to fabrication of the crown 80, a layer of the adhesive 100may be applied to exposed portions of the abutment 50 and implant 20(i.e., outer surface of the abutment proximal portion 58 and outersurface of the implant proximal segment 34). The crown 80 may be then beattached to those portions of the abutment 50 and implant 20 which arecovered by adhesive 100. Such attachment results in the implant abutmentjoint 44 being completely covered by the crown distal portion 86.Furthermore, such attachment results in the flow of adhesive 100 betweenthe crown cavity 90 and the outer surface of the implant proximalsegment 34.

The adhesive 100 preferably extends between the crown cavity 90 and theouter surface of the abutment proximal portion 58. For configurations ofthe implant 20 wherein the implant proximal segment is formed at anangle α₂ as steep as 3° as shown in FIGS. 8 a and 9 a, the abutment neck64 results in the creation of an annular void between the crown cavity90 and the implant 20/abutment 50. Advantageously, such annular voidprovides an area within which excess adhesive 100 may collect to avoidthe undesirable effects of hydraulic pressure build-up of adhesive 100that may otherwise occur between the crown 80 and implant 20/abutment50.

The curing of the adhesive 100 results in sealing of the implantabutment joint 44, the crown implant joint, and the abutment crown joint70. Such sealing eliminates the susceptibility of such joints tobacterial invasion or other deteriorations. Furthermore, the uniqueinterface between the implant proximal segment 34 and the abutment 50prevents micro-movement of the abutment 50 and the crown 80 relative tothe implant 20. Furthermore, the integrity of the adhesive 100 is alsoimproved such that the susceptibility to fractures and resultantbacterial invasion is lessened.

The above description is given by way of example, and not limitation.Given the above disclosure, one skilled in the art could devisevariations that are within the scope and spirit of the inventiondisclosed herein. Furthermore, the various features of the embodimentsdisclosed herein can be used alone or in varying combinations with eachother and are not intended to be limited to the specific combinationdescribed herein. Thus, the scope of the claims is not to be limited bythe illustrated embodiments.

1. A dental prosthesis, comprising: an implant having distal andproximal portions, the implant proximal portion including distal andproximal segments, the implant proximal segment defining an implantproximal end, the implant proximal segment having an annularly taperedouter surface extending from the implant proximal end and defining aconical shape, the annularly tapered outer surface defining a diameterthat increases from a minor diameter to a major diameter as the distancefrom the implant proximal end increases; an abutment having distal andproximal portions defining an abutment shoulder therebetween, theabutment proximal portion including an abutment collar, the abutmentproximal portion having an annularly tapered inner surface extendinginto the abutment proximal portion from the abutment collar to define anabutment cavity, the abutment collar defining a diameter being less thanthe major diameter and greater than the minor diameter, the annularlytapered inner surface engaging the annularly tapered outer surface ofthe implant proximal segment with a portion of the implant beingreceived within the abutment cavity to define an implant abutment jointtherebetween; and a crown configured to be positioned over the abutmentand the implant such that the crown covers the implant abutment joint.2. The dental prosthesis of claim 1 wherein the abutment cavity isformed complementary to the annularly tapered outer surface tofacilitate circumferential engagement of the abutment shoulder to theannularly tapered outer surface.
 3. The dental prosthesis of claim 2wherein the tapered outer surface is conically shaped and having a halfangle of about 45 degrees.
 4. The dental prosthesis of claim 1 whereinthe implant distal segment is cylindrically shaped.
 5. The dentalprosthesis of claim 1 wherein the implant distal segment defines acircumferential undercut between the implant distal portion and theimplant proximal segment.
 6. The dental prosthesis of claim 5 whereinthe undercut has an arcuately shaped cross section.
 7. The dentalprosthesis of claim 1 wherein the abutment has an abutment neck disposedadjacent the abutment distal end, the abutment neck having a reducedcross section in an axial direction.
 8. The dental prosthesis of claim 1wherein: the crown includes a crown distal portion defining a crowndistal end having a crown cavity formed therein; the crown cavity beingconfigured complementary to the abutment proximal segment such that thecrown distal end circumferentially engages the implant proximal segment.9. The dental prosthesis of claim 1 wherein: the receipt of the abutmentproximal portion and the abutment proximal segment into the crown cavityresulting in the engagement of the crown distal portion to the outersurface of the implant proximal segment such that the crown implantjoint is defined therebetween; the implant abutment joint being coveredby the crown distal portion; a layer of adhesive being disposed betweenthe implant proximal segment and the crown cavity at the crown implantjoint.
 10. The dental prosthesis of claim 1 wherein: implant proximalportion defines an implant proximal end having an implant aperturedisposed therein; the abutment includes abutment proximal and distalportions, the abutment distal portion being configured to be insertableinto the implant aperture.
 11. The dental prosthesis of claim 1 whereinthe abutment proximal portion has a frusto-conical outer surface. 12.The dental prosthesis of claim 1 wherein the implant proximal segmenthas a concave cross section.
 13. The dental prosthesis of claim 12wherein: the implant proximal segment is defined by upper and lowerconical surfaces; the lower conical surface extending upwardly from theprosthetic margin and having a half angle of up to about 45 degrees; theupper conical surface extending downwardly from the implant proximal endand having a half angle of up to about 5 degrees; a radius being formedbetween the upper and lower conical surfaces.
 14. The dental prosthesisof claim 13 wherein: the implant proximal segment has a height of about1 millimeter (mm); the upper conical surface intersecting the radius ata tangent thereof; the concave cross section being configured such thatthe tangent is offset radially inwardly from the prosthetic margin byabout 0.2 mm to about 1 mm.
 15. A dental prosthesis, comprising: animplant having distal and proximal portions, the implant proximalportion including distal and proximal segments, the implant distalsegment defining a circumferential undercut between the implant distalportion and the implant proximal segment, the implant proximal segmenthaving an implant proximal end, the implant proximal segment having anannularly tapered outer surface extending from the implant proximal endand defining a conical shape, the annularly tapered outer surfacedefining a diameter that increases from a minor diameter to a majordiameter as the distance from the implant proximal end increases; anabutment having abutment distal and proximal portions and defining anabutment shoulder formed therebetween, the abutment proximal portionincluding an abutment collar, the abutment proximal portion having anannularly tapered inner surface extending into the abutment proximalportion from the abutment collar, the abutment proximal end defining adiameter being less than the major diameter and greater than the minordiameter, the annularly tapered inner surface engaging the implantproximal end such that an implant abutment joint is definedtherebetween; and a crown configured to be positioned over the abutmentand the implant such that the crown covers the implant abutment joint.16. The dental prosthesis of claim 15 wherein the undercut has anarcuately shaped cross section.
 17. A dental prosthesis, comprising: animplant having distal and proximal portions, the implant proximalportion including distal and proximal segments, the proximal segmenthaving a concave cross section, the implant proximal segment having animplant proximal end, the proximal segment defining a diameter thatincreases from a minor diameter to a major diameter as the distance fromthe implant proximal end increases; an abutment having abutment distaland proximal portions and defining an abutment shoulder formedtherebetween, the abutment proximal portion including an abutmentcollar, the abutment proximal portion having an annularly tapered innersurface extending into the abutment proximal portion from the abutmentcollar, the abutment proximal end defining a diameter being less thanthe major diameter and greater than the minor diameter, the annularlytapered inner surface engaging the implant proximal segment such that animplant abutment joint is defined therebetween; and a crown configuredto be positioned over the abutment and the implant such that the crowncovers the implant abutment joint.
 18. The dental prosthesis of claim 17wherein: the proximal segment is defined by upper and lower conicalsurfaces; the lower conical surface extending upwardly from theprosthetic margin and having a half angle of up to about 45 degrees; theupper conical surface extending downwardly from the implant proximal endand having a half angle of up to about 5 degrees; a radius being formedbetween the upper and lower conical surfaces.
 19. The dental prosthesisof claim 18 wherein: the upper segment has a height of about 1 mm; theupper conical surface intersecting the radius at a tangent; the concavecross section being configured such that the tangent is offset radiallyinwardly from the prosthetic margin by about 0.2 mm to about 1 mm. 20.The dental prosthesis of claim 19 wherein: the crown includes a crowndistal portion defining a crown distal end having a crown cavity formedtherein the crown cavity being configured complementary to the abutmentproximal segment such that the crown distal end circumferentiallyengages the implant proximal segment.